A method of removing a stator coil (10) from a stator core (12) of an electrical generator, including vibrating an unbonded portion (50) of the coil (10) until a resin bond material (32) between a bonded portion of the coil (46) and a surface (34) of the core (12) fails due to high cycle fatigue to free the coil (10) from the core (12).
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1. A method of removing a stator coil from a stator core of an electrical generator, comprising:
vibrating an unbonded portion of the coil until a resin bond material that forms a bond between the coil and a surface of the core begins to fail due to high cycle fatigue;
continuing to vibrate the unbonded portion until all the resin bond material fails, thereby breaking the bond; and
removing the coil from the core once the bond is broken.
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monitoring motion of the unbonded portion of the coil during the vibration; and
controlling the vibration in response to the monitored motion.
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The invention relates generally to stator rewind procedures for electro-dynamic machines. More particularly, this invention relates to removing a stator coil from a stator core of an electrical generator when the coil has been resin bonded to the core.
In many modern generators the stator coil includes conductors separated and wrapped with a tape, e.g. a mica tape. This assembly is impregnated with a resin insulation that removes air, gas, and moisture, to provide a void-free insulation. In some generators the coil is impregnated first and then assembled to the core. In other generators the coil and core are assembled first, and the entire assembly is impregnated with the resin in a process to form a monolithic stator assembly. An example of this process is Global Vacuum Pressure Impregnation (GVPI). In a GVPI process the stator assembly is processed in an alternating vacuum and pressure environment that ensures uniform distribution of resin throughout the assembly. The resin is cured to form the monolithic stator assembly. Benefits of GVPI include improved structural strength and improved resistance to moisture and chemicals etc.
When a stator rewind is necessary, where the stator coils must be removed and replaced, each coil must be removed from a slot within the stator. The coil is resin bonded into the slot, and the bond is necessarily strong. Conventional practice has been to engage the end windings of the coil and to pull them upward out of the slot with enough mechanical force to extract the coil. However, this leaves a lot of the resin still bonded to the surface of the slot, and a subsequent operation is necessary to remove the residual resin from the surface of the slot. This subsequent operation is labor intensive and time consuming.
The invention is explained in the following description in view of the drawings that show:
The present inventor has recognized that the traditional method of coil removal by mechanical force actually tears the tape present on the windings, yet leaves the resin bond to the stator slot surface largely intact. The inventor further recognized this to be a result of a greater mechanical strength of the bond than the tape, which enables the bond to resist the mechanical extraction force until after the tape has yielded. The inventor further recognized that the resin bond is more rigid than the tape, and as a result is likely to have a lower resistance to high frequency mechanical fatigue than the tape. As a result the inventor has developed an innovative approach to removing the coil from the core that targets the weaker fatigue strength of the bond such that the bond breaks due to fatigue while the tape remains intact. Specifically, by applying high frequency vibrations to the coil, the bond is repeatedly stressed by the vibration forces until it breaks. However, because the tape is capable of withstanding these low displacement/high cycle forces better than the bond, it remains intact. When the process is complete, the coil is freed from the stator, the resin bond is destroyed, and only a reduced amount of the resin is left adhered to the slot. An advantage of this process is the reduced amount of time required for resin removal from the slot subsequent to the coil removal.
The method disclosed herein includes vibrating the coil 10 in such a way that the resin bond material 32 reaches its fatigue limit before the external tape 28 reaches its fatigue limit. Due to the inherent characteristics of the materials, this can be accomplished by attaching a vibration inducing device 40 to the coil. Inducing vibration for a sufficient time causes the resin bond material 32 to reach its fatigue limit first, such that a crack forms in the bond 30 which begins to propagate along the bond 30, thereby breaking the bond 30. When the crack has propagated the entire original length LBO of the bond the coil 10 is fully freed from the slot 18.
So long as the yield strength of the external tape 28 is not exceeded by the vibration induced forces, nearly any frequency and amplitude of vibration may be selected. It is estimated that vibration amplitudes up to 0.100 inches (2.54 mm) may be permissible, however, this may vary in different applications. In an exemplary embodiment, a frequency and amplitude of vibration may be applied to the coil without change until the bond is broken. Alternately, the vibration device 40 may vary frequencies in any number of patterns. For example, the vibration device may be capable of delivering a range of frequencies, and the frequencies selected may vary within that range over time. It may vary in a step wise manner, where a first frequency is selected, and then a second etc. It may vary in a cyclic manner, such that the frequencies applied to the coil 10 sweep from lowest to highest etc. The range applied may or may not be adjustable. Any number of other loadings may be envisioned. Other scenarios include ramping the frequency, either from low to high or from high to low. Further, random frequencies may be employed. Any combination of the above is likewise possible.
In addition to varying the frequency, the amplitude may be varied in a manner similar to how the frequency is varied. In particular, the amplitude of the vibrations may remain the same, may be stepped or ramped up or down, may cycle, and/or may be random. Further, instead of vibrations, an impulse loading may be employed. The frequency and the amplitude of the impulse may be varied just as they may be for the vibrations. In all instances the frequency and amplitude may be changed in unison with each other or independent of each other.
The amount and frequency of the force imparted to the bond at the leading edge of the crack may be controlled to maximize a speed of the process. Fatigue failure is influenced both by a magnitude of applied force and a frequency of application. Increasing either the magnitude or frequency of applied force decreases the amount of time it takes for the fatigue failure to occur. However, the method requires that the magnitude of the force applied to the resin bond material 32 not exceed a mechanical yield strength of the external tape 28. Consequently, in order to reduce the amount of time it takes to break the bond it may be desired in some embodiments to monitor the system to ensure a maximum acceptable force is applied at the maximum possible frequency to the leading edge 42 of the crack.
The amount of force felt by the leading edge 42 of the bond 30 for every cycle of vibration depends on an amplitude of vibration of the unbonded portion 50. In order to maximize an amplitude of vibration for a given vibratory input delivered by the vibration device 40, in an exemplary embodiment a natural frequency may be considered. The vibrating assembly includes those parts subject to vibratory induced movement. This may include the unbonded portion 50 and the vibration device 40 if the vibration device 40 is attached to the unbonded portion 50, since each influences the natural frequency at which the unbonded portion 50 will vibrate. A natural frequency of the vibrating assembly is related to both a mass and a length of the vibrating assembly. However, it can be seen that the unbonded portion 50 will change its unbonded portion length LUP as the leading edge 42 of the crack moves along in direction 44, which necessarily changes the mass and length of the vibrating system. This change in mass and length LUP of the unbonded portion 50 will change the natural frequency of the vibrating system as the crack progresses. An increase in the mass and unbonded portion length LUP will likely lower the natural frequency. Consequently, in an exemplary embodiment, the frequency of vibration imparted by the vibration device 40 may vary as a natural frequency of the vibrating assembly changes. This change in natural frequency may be sensed by sensors 56, such as accelerometers, that may be used to monitor for motion.
There may be a fundamental frequency and other resonant frequencies that are multiples of the fundamental frequency for the vibrating assembly. In an embodiment where more than one resonant frequency is present in the vibrating system, the highest resonant frequency the vibration device 40 can deliver may be selected. By doing this, the time it takes to reach fatigue failure is reduced because for any given time period more cycles are delivered at a higher frequency than at a lower frequency.
It may be desired to remove a portion of the end winding 14 before operating the vibration device 40. Trimming a portion of the unbonded portion 50 yields a trimmed unbonded portion 50 with a reduced mass, which increases the natural frequency of the trimmed vibrating system. Vibrating at or near this increased natural frequency in turn reduces the amount of time it takes to reach the fatigue failure at the leading edge 42. In an exemplary embodiment, once the leading edge 42 of the crack has propagated far enough along the original length LBO of the bond 30, the vibration device 40 may be unsecured from its original location and moved in the direction 44 closer to the leading edge 42 of the crack, where it is secured into a subsequent location. In addition to this repositioning of the vibration device 40, as described above, some (or some more) of the unbonded portion 50 may be trimmed and the trimmed vibrating assembly may continue to be vibrated. Trimming some (or some more) of the unbonded portion 50 increases the natural frequency of the trimmed vibrating assembly, which in turn decreases the amount of time before fatigue failure occurs at the leading edge 42 of the crack. This repositioning and trimming may be repeated as many times as is desired to propagate the crack the full original length LBO of the bond 30. Trimming as much of the unbonded portion as is possible will produce the highest natural frequencies, and hence the quickest time to fatigue failure.
Vibrating an unbonded portion 50 of a coil 10 may produce complex waveforms. This is represented schematically by waveform 60 shown in
In this exemplary embodiment only a single coil 10 is shown, and the vibration device 40 is shown as secured only to the single coil 10. However, often there may be two coils in a given core slot 18. The vibration device 40 could be secured to two different coils simultaneously, or a separate vibration device 40 could be attached to each coil. In such an exemplary embodiment, vibrations could be applied without regard for natural frequency. Alternately, the unbonded portions could be monitored and the frequency of vibration adjusted as the natural frequency of the system changes.
The novel method of removing a stator coil from a stator core disclosed herein greatly improves stator rewind procedures. It simplifies removal of the coil by eliminating the need for mechanical systems large enough to forcefully extract the coil from the core. It reduces damage to the coil because the resin bond external to the core is broken, not the external tape that is part of the coil. It reduces the amount of resin left in the slot, and this reduces the effort and time required, for the subsequent final removal of any remaining resin from the core slot. Together these improvements yield a decrease in downtime and cost associated with a stator rewind.
While various embodiments of the present invention have been shown and described herein, it will be obvious that such embodiments are provided by way of example only. Numerous variations, changes and substitutions may be made without departing from the invention herein. Accordingly, it is intended that the invention be limited only by the spirit and scope of the appended claims.
Ford, Keegan M., Humphries, Benjamin T.
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Apr 03 2012 | FORD, KEEGAN M | SIEMENS ENERGY, INC | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 028003 | /0610 | |
Apr 03 2012 | HUMPHRIES, BENJAMIN T | SIEMENS ENERGY, INC | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 028003 | /0610 | |
Apr 06 2012 | Siemens Energy, Inc. | (assignment on the face of the patent) | / |
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